Some characteristics of hyperoxia-adapted HeLa cells. A tissue culture model for cellular oxygen tolerance.

By culturing HeLa cells at stepwise increased oxygen tensions over a prolonged period of time (approximately 21 months) we selected a substrain capable of growing under 80% O2/19% N2/1% CO2, an oxygen level that is lethal to normal HeLa cells, adapted to 20% O2/79% N2/1% CO2. The 80% O2-adapted cells exhibited the following characteristics. At the ultrastructural level an abnormal mitochondrial morphology was observed: compared to normal cells, mitochondria of the hyperoxia-adapted cells exhibited a 3-fold larger mean profile area in sections and were slightly decreased in number; the relative mitochondrial volume was increased 2-fold, whereas the size of both cell types was the same. Mitochondrial matrix appeared less dense in the hyperoxia-adapted cells; no structural damage was detected. Compared to the 20% O2-adapted cells O2 consumption per cell was approximately 40% decreased in the 80% O2-adapted cells. Under hyperoxic conditions 20% O2-adapted and 80% O2-adapted cells exhibited very similar cyanide-resistant respiration rates (0.16 +/- 0.04 and 0.15 +/- 0.02 fmoles/cell/minute, respectively), suggesting that the increased O2 tolerance of the 80% O2-adapted cells was not due to a decreased cellular production of activated oxygen species at hyperoxia. Cellular levels of the enzymes directly involved in protection against activated oxygen species, i.e., superoxide dismutases, catalase, and glutathione peroxidase, were normal or slightly below normal in the 80% O2-adapted cells, implying that these enzymes were of no significance for the increased O2 tolerance. In addition, the specific activity of glucose-6-phosphate dehydrogenase, a key enzyme for cellular production of NADPH, was not related to the degree of O2 tolerance. Our results suggest that the increased O2 tolerance of the 80% O2-adapted cells is neither based on cellular properties controlling the formation or removal of intracellular activated oxygen species nor on the cellular capacity to repair or replace damaged cellular components. We speculate that the increased O2 tolerance is largely due to a genetically determined increased resistance of oxygen-sensitive cellular targets.

HeLa cell variants that differ in sensitivity to monofunctional alkylating agents, with independence of cytotoxic and mutagenic responses.

Different strains of the established human cell line HeLa differ substantially in sensitivity to ethyl methanesulfonate (EtMes). The EtMes doses effective for either cytotoxicity or mutation induction in a line of HeLa S3 cells are about 1/10th those required in the CCL2 HeLa line of the American Type Culture Collection. By plating the sensitive HeLa S3 line in the presence of highly cytotoxic doses of EtMes, we obtained a clone (designated A6) that displays about 7-fold greater resistance to EtMes toxicity. This A6 isolate is also cross resistant to other simple monofunctional alkylating agents-exhibiting about 4-fold increased resistance to methyl methanesulfonate and 10- to 15-fold increased resistance to N-methyl-N'-nitro-N-nitrosoguanidine but is similar to the S3 parent in sensitivity to mitomycin C, UV radiation, and gamma-rays. In contrast to the results for cytotoxicity, the A6 variant and the S3 parent showed the same high susceptibility to EtMes induction of ouabain-resistant mutations. This is direct biological evidence that different alkylation lesions are normally responsible for mutagenic and cytotoxic effects. The S3 and A6 cell lines may differ in DNA repair capability specific to certain potentially lethal alkylation products. The comparative sensitivity of the A6 cells to alkylation mutagenesis may also prove useful in cell genetic studies by facilitating the generation of multiple mutants for recessive alleles and permitting exceptionally sensitive detection of specific mutagenic effects.

Cell surface coatings and membrane potentials of malignant and nonmalignant cells.

A positive surface potential indicating a cell coating is common to malignant cells, lymphocytes, and normal and malignant trophoblastic cells. This characteristic was not generally found for other normal cell types tested by microelectrode penetration.